Apparatus for the manufacture of rayon



March 9, 1943. w, ss 2,313,140

APPARATUS FOR THE MANUFACTURE OF RAYON Filed May 1, 1940 "8 Sheets-Sheet 1 IN VENTOR ATTORNEYS.

March 1943- I w. H. FURNESS APPARATUS FOR THE MANUFACTURE OF RAYON Filed May 1, 1940 s Sheets-Shee t 2 INVENTOR.

ATTORNEYS.

March 9, 1943, w. 'H. FURNESS APPARATUS EOR THE MANUFACTURE OF RAYON Filed May 1, 1-940 8 Sheets-Sheei IIQVENTOR. I

MATMW ATTORNEY! March 9, 1943 W. H. FURNESS APPARATUS FOR THE MANUFACTURE OF RAYON Filed May 1, 1940 8 Sheets-Sheet 4 I N VEN TOR:

W ATTORNEYS.

March 9, 1943. w. H. FURNESS APPARATUS FOR THE MANUFACTURE OF RAYON Filed May 1, 1940 8 Sheets-Sheet 5 IN VEN TOR:

MWQLM A TTORNEYS.

March 9, 1943. W. H. FURNESS 2,313,140

APPARATUS FOR THE MANUFACTURE )F-RAYON Filed May l, 1940 8 Sheets-Sheet-7 INVENTOR:

ATTORNEYS.

March 9, 1943. w. H. FURNESS I APPARLXTUS FOR THE MANUFACTURE OF HAYON Filed May 1, 1940 8 Sheets-Sheet 8 l INVENTOR:

wfl rw ATTORNEYS.

Patented Mar. 9, 1943 UNITED STATES PATENTVOFFICEV APPARATUS roa lir i n itnnumc'runn or William H. Furness, Haddonfield, N. J., assignor to American Rayon Company, Inc., Riverton, N. J., a corporation of New Jersey Application May 1,1940, Serial -No.332,693

8 Claims. (Cl. 242-53) This invention relates to apparatus for the manufacture of rayon, and is particularly useful in the manufacture of cuproammonium rayon. Its nature, objects and advantages will appear from the following description.

The method and apparatus will first be generally described and then the detailed features of construction, reference being had to the ac companying drawings wherein- Figure 1 is a more or less diagrammatic elevational view of an apparatus for carrying out my invention;

Figure 2 is a broken out diagrammatic elevational view of a cage employed;

Figure 2a is a diagrammatical elevational view of the cage shown in Figure 2 with certain other parts of the apparatus, some of which appear in section, shown associated therewith;

Figure 2b is a fragmentary cross section taken substantially on the line 2b-2b of Figure 2a;

Figure 2c is a'fragmentary cross section taken substantially on the line 20-20 of Figure 2a;

Figure 3 is an enlarged detailed end view of the cage which is diagrammatically shown in Figure 2 taken on the line 3-3 of Figure 4;

Figure 4 is a fragmentary longitudinal section taken substantially on the line 4-4 of Figure 3 and illustrating one end portion of the cage;

Figure 5 is a fragmentary longitudinal section similar to Figure 4 but illustrating the other end portion of the cage and associated operating mechanism;

Figure 6 is a cross section taken on the line 6-6 of Figure 5;

Figure '7 is a cross section taken on the line l! of Figure 5;

Figures 8, 9,10 and 11 are fragmentary cross sections taken on the lines 88, 9-9, Ill-I and lI-ll respectively of Figure Figures 12 to inclusive are diagrammatic side views illustrating various positions assumed by the bars of the cage shown in Figures '3 and 4 during one complete cycle of their movements;

Figures 12a to 20a inclusive are diagrammatic end views corresponding to Figures 12 to 20 inclusive;

Figure 21 is an end view taken on the line 2l-2l of Figure 22 illustrating another cage employed in the apparatus onto which the thread is laid before it is led to the cage shown in Figure 2;

Figure 22 is a fragmentary longitudinal section taken substantially on the line 22-22 of Figure 21;

Figure 23 is a cross section taken on the line 23-23 of Figure 22 but only illustrating certain of the bars of the cage of Figure 21 and the actuating parts therefor; and

Figure 24 is a cross section taken on the line 2424, of Figure 22 illustrating the remaining bars of the cage and the actuating parts therefor.

The cuproammonium cellulosic spinning solution is preferably made in accordance with my Patent No. 2,225,431, dated December 17, 1940, if wood pulp be employed, and according to my Patent No. 2,247,124, dated June 24, 1941, if cotton linters be employed.

Referring now particularly to Figures 1, 2, 2a, 2b, and 2c, the cellulosic solution is pumped from a. suitable source of supply to the spinnerets l in the caustic soda setting bath A. They caustic soda setting bath has a concentration of from about 25 to 45 grams per liter of NaOH, depending upon such considerations as the concentration of the cellulose in the spinning solution. The spinnerets preferably discharge upwardly and the setting bath is circulated as described in my copending application Serial No. 332,694, filed May 1, 1940. The number of spinnerets employed varies, dependent upon how heavy a bundle of filaments it is desired to produce and ,treat. The bundles of filaments delivered by the spinnerets are gathered into a single bundle after passing suitable guides 8, and the bundle is led over a driven roll 9 and thence passed around an idler roll 10 and laid up in the form of acontinuously advancing helix on the rotating cylindrical cage B, the construction and opera tion of which will be later described. From the cage B the bundle of filaments is led over an idler II to a similar cylindrical cage C upon which the bundle is laid in the form of a continuously advancing helix, as indicated in Figure 2.

On the rotating cylindrical cage B, the turns of the bundle are subjected to a water wash which is preferably hot. The water wash is introduced by means of a perforated pipe I2, and the water dripping on the upper part of the cage collects in the bottom in a suitable pan l3 in which, located slightly below the normal water line, is a series of nozzled pipes M of similar construction to those shown in' Figures 2a and 2b, which will be later described. Air is delivered to these pipes and has the effect of blowing up wash liquor against the bottom of the cage. In consequence, the filaments of the bundle are efiectively subjected to the hot water wash which has the effect or removing the bulk of the caustic soda. the ammonia and a substantial portion oi the copper in the filaments. Hot water is used in preference to cold water, for the reason that caustic soda is more soluble in hot water and therefore the removal of the caustic soda, ammonia and copper can be efiected with a smaller quantity of water than would otherwise be required.

The wash liquor collected from beneath the cage contains caustic soda, ammonia, copper, and some sodium sulphate, the chemicals being recovered in the -manner shown and described in my copending application Serial No. 332,694, filed May 1, 1940. i

Some of the ammonia in the filaments is evaporated as gas by the hot water and in order to collect this, the cage is enclosed in a housing l5 having a suction outlet it for carrying off the ammonia gas along with air, for subsequent recovery of the ammonia as ammonia water, as described in my aforesaid copending application.

The bundle of filaments, now largely freed of caustic soda, or the ammonia, and of a substantial part oi the copper, is first subjected on the cage C to a sulphuric acid wash solution, the solution being'supplied bythe perforated pipe H, as shown in Figure 2a. The acid wash solution runs down over the cage and is collected in the pan l8 and serially fiows into a succession of troughs l9 which are downwardly inclined toward the center, crosswise oi the cage, and also lengthwise oi the cage. The first trough fills, overflows, runs into the next trough which overflows, and so onuntil the acid reaches the central discharge outlet 20, which discharges into a reservoir 2!. In each trough there is a nozzled pipe 22, fed from a manifold 23 with compressed air, sothat the acid wash liquor is blown up against the bottom of the cage.

, In consequence, the filaments of the bundle are effectively subjected to the acid wash and the remaining caustic soda and copper are removed from the filaments.

By virtue of the fact that most of the caustic soda, the ammonia and a substantial part of the copper have been previously removed by the hot water wash, a relatively small amount of sulphuric acid is required in the acid section. It will also be noted that the fresh acid solution is applied to the beginning of the helix and only for a short distance; and that the acid solution collecting-therebeneath is fed in the direction of the advance of the helix so that the strongest solution is applied at the beginning of the helix and. as the solution becomes weaker, it is successively applied to portions or the bundle progressively containing less caustic soda and copper, and this despite the fact that the cage C is horizontally disposed. v

The acid and the soluble salts in and on the bundle o1 filaments are removed by a water wash supplied through the perforated pipe 24. The drippings from the first portion of this pipe are directed bmthe inclined baiile 25 into the right hand trough of the succession of troughs i9, the collected wash water overflowing into the next trough and soon until the wash liquor discharges through the ;pipe 20 into the vessel 2|, along with the acid wash liquor proper. The purpose of this is to recover acid and copper, it being noted that the filaments leaving the acid section proper contain a substantial amount of acid and some copper. The remaining portion or the wash liquor collecting in the pan 29 contains so little acid and copper that it may be discarded, if desired.

After the final wash section, the helix issub- Jected to a drying operation, hot air being supplied to the enclosing casing 21. To permit of shrinkage during the drying, it is preferable to taper the cage at the drying end portion, as indicated at 28.

Referring back to the spinning and the hot water wash treatment, the spinning solution or "goo" is fed to the spinnerets in constant volume, and the roll 9 is driven at constant speed as is the cage B. The roll is driven at a constant speed coordinated with the rate of delivery of the spinnerets,whereby breaking oil of the filaments is avoided. It is apparent that the lineal speed of the cage B is greater than the rate of spinning, the result of which is to stretch the bundle of filaments. This stretching is such as would cause breakage at the spinnerets. By interposing the roll 9, which is driven at a con: stant speed coordinated with the rate of spinning, the greater portion of the stretching occurs between the cage B and the roll 9. One advantage of the foregoing is that loosening of the turns of the helix on the cages is prevented during liquid treatment. The stretching also expresses some liquid from the bundle which is advantageous in such respect. Furthermore, it makes it possible to spin a cellulosic spinning solution of relatively high viscosity. The higher the viscosity of the spinning solution, the more slowly must it be spun into the setting bath and the more slowly must the draw roll be rotated. While, therefore, in such case, the spinning solution is being slowly spun into the setting bath, yardage is gained by the stretching so that the cage B and the cage C can be operated at a sufficiently rapid rate for commercial production.

For some classes of work, the'end product might be too low in elongation, because the stretching has the effect of decreasing the elongation property of the filaments. therefore, it is preferable to provide means whereby the elongation lost during the stretching may be regained in whole or in part. To this end, I provide a ribbed, corrugated roll 29 at the drying end portion of the cage C as diagrammatically indicated in Figure 2a. The ribs or corrugations 39 on the roll 29 fit between the spaces, 1. e., interleave with the bars, of the cag C, as shown in Figure 2c. The eifect is to crimp the bundle and to spread the filaments somewhat, in consequence of which, as drying proceeds, the bundle of filaments has opportunity for free shrinkage. during which shrinkage, elongation lost during the stretching is regained, the extent of elongation regained being dependent upon the adjustment of the roll 29 toward and away from the cage. In cases where it is unnecessary to regain elongation, the roll 29 is adjusted to an inoperative position. The roll 29 is of course an idler roll and is driven by the cage C. In addition, it is pointed out that the roll 29 is advantageous in that, due to the crimping of the thread, it keeps the thread feeding along at the tapered end of the cage, and also separates the filaments oi the thread somewhat to give more effective drying.

It is to be understood that when the bundle is dried, it is continuously drawn oil from the drying end of the cage C and laid upon any suitable holder, in the case of long filament rayon. In the case of rayon staple, the bundle may be led onto a conveyor in the usual manner, either before For suchclasses of work,

or after drying, and cut into the desired lengths on the conveyor; or it may be cut on the drying end of a cage, as shown in my copending application Serial No. 269,881, filed April 25, 1939. In the case of staple, a very fat bundle will be spun,

for which purpose a greater number of spinnerets would be cut in. In the case of long filament plicity of bars mounted for radial in and out and longitudinal back and forth movement, the bars.

being arranged-in concentric formation in two sets with the bars 3| of one set in circumferentially evenly spaced interspersed relation with the bars 32 of the other set. The bars of each set are arranged in groups and, in this instance, I have shown each set of bars arranged in four groups, with each group including nine bars. The bars 3| are secured at spaced intervals along their length to arcuate supports 33, having radially disposed rods 34 which slidingly fit the radial spokes 35 of hub members 36. Similarly, the bars 32 are secured at spaced intervals along their length to arcuate supports 31 having radially disposed rods 33 which slidingly fit the radial spokes of cams 53 and 51 and a worm wheel 58 are keyed on the cam shaft 52 for imparting radial in and out movement to the bars 3| and 32 of the cage in a predetermined timed relation.

The cams referred to are rotated by means of a drive shaft 59 connected to any suitable source of power, and a worm 60 keyed onthe shaft and meshing with the worm wheels 55 and 58;. The shaft 53 is rotatably mounted in a fixed bearing GI and in the end portion 48b of the shaft 4|.

It is pointed out that since the worm wheel 42 is keyed on the shaft 4| and'since the bearing member 48 in which the .cam shafts are tion 48d of the member 48 rides.

they are being bodily rotated around the axis of the shaft 4|. w

The cam 53 is operatively connected to the bars 3| to impart back and forth movement 39 of hub members 40, it being noted that the hub 'central longitudinal driven shaft 4| so as to rotate therewith and to be adapted for movement I longitudinally back and forth on the shaftas will further appear. A Worm wheel 42 is keyed on the shaft4| and is rotated by a worm 43 having driving connection with a suitable source of power.

Collars 44 and 45 splined on the shaft 4| are located adjacent the hub members 36 and! respectively, and are adapted to be shifted longitudinally back and forth on the shaft independently of the back and forth movement imparted to the hub members. The collars 44 are connected to the arcuate members 33 by means of links 46 and the collars 45 are connected to the arcuate members 31 by means of links 41 and, therefore, when the collars are moved toward and away from their associatedhub members, the connected arcuate membe'rslwith their bars are moved radially in and out.

Referring particularly to Figures 5 and 6, a cam mechanism indicated as a whole by the reference letter D is illustrated for imparting the radial in and out and longitudinalback and forth movement to the bars above referred to. This cam mechanism comprises a supporting or bearing member 48 secured to the worm wheel 42 to rotate therewith, and having a bore 43a for receiving the end portion 48b of the shaft 4| and transversely extending bearings 43 and 50 for the cam shafts 5| and 52. A pair of cams 53 and 54 and a worm wheel 55v are keyed on the cam shaft 5| for imparting longitudinal back and forth movement to the bars 3| and 32 of the cage in a predetermined timed relation, anda pair thereto by means of a horizontally disposed bar 62, slidingly mounted in the worm wheel 42 having a roller 63 at one end riding on the cam surface ofthe cam ,53 and having a longitudinally reciprocable rod 64 connected to its other end,

by an arm 65. The rod 64 is securedto the hub members 35 which have connection with the bars 3| in the manner above described The roller 63 is yieldingly maintained in contact with the cam 53 by means of a spring 63a connected at one end to the worm wheel 42 and at its other end to a pin 53b carried by the arm 65.

Similarly the cam 54 is operatively connected to the bars 32 to impart back and forth moveits other end to appin 61b carried by the arm 69. The cam 56 is operatively connected to the.

bars 3| to impart radial in and out movement thereto by means of a horizontally disposed bar 10 slidingly mounted in the worm wheel 42 having a roller H at one end riding on the cam surface of the cam 56 and having a longitudinally reciprocable rod 12' connected to its other end by scribed yieldingly maintain the rollers II and 15 in contact with the cams 56 and 51.

Referring now to Figures 12 to 20 inclusive and 12a to 20a inclusive, it will be seen that I have therein diagrammatically shown by means of two adjacent bars 3| and 32, a series of views illustrating various relative positions taken by the bars during one cycle of their movements, i. e.,

during the time that the cams 53, 54, 56 and 51' make one revolution on their axes.

In these views, the dimension indicated at a in Figure 12 represents the length of the back and forth movement of the bars and the dimension b in Figure 13 represents the amount of in and out movement of the bars. The short dotted lines and arrows c indicate the path of the bars 3| and the longer dotted lines and arrows d indicate' the path of the bars 32.

In Figures 12 and 20, the bars are shown in the same positions as they appear in Figures 4 and 5. The position illustrated in Figure 12 will be assumed to be the starting point in describing one cycle of movement of the bars. As the cams 33, M, 56 and 51 rotate in the directions of the arrows indicated in Figure the bars 3i first move to the right while remaining in their outer- It is to be noted that both of the sets of bars 3i' and 32 move to the right while in their outermost positions during the portion of the cycle between the positions shown in Figures 15 and 16. This portion of the cycle is preliminary, so to speak,

-to the support of thethread being transferred from the bars 3!, which are just completing their forward stroke, to the bars 32 which are just starting on their forward stroke. 1

From the position shown in Figure 16, the bars 3i move to the left and inwardly to the point shown in Figure 17. then to the left while remaining in innermost position to the point shown in Figure 18, then to the left and outwardly to the point shown in Figure 19, and then to the right while remaining in outermost position to the point shown in Figure 20. It is to be noted that both sets of bars 3| and 32 move to the right while in their outermost positions during theportion of the cycle between the positions shown in tion and started moving to the right. If this Figures 19 and 20, this being similar to,the action taking place between the positions shown in Figures 15 and 16 with the exception that in Figure 15 the bars 32 are in their extreme left hand positions and the bars II have not quite reached the end of their right hand movement, while in Figure 19 the bars ii are in their extreme left hand positions and the bars 32 have not quite reached the end of their right hand movement. In other words, inthe position of the bars shown in Figure 15, support of the thread is about to be transferred from the bars 3! to the bars 32 while in the position shown in Figure 19 support of .the thread is about to be transferred from the bars 32 back to the bars 3i again.

When the bars are in outermost position and moving to the right they contact the thread on the cage and move it to the right to lay it up in the form of a continuously advancing helix, as shown in Figure 2 and when the bars are in inher position and moving to the left they are out of contact with the thread. The overlap of moveshould happen there would be a loosening of the thread on the cage and an interruption in the helical advance of the thread.

With reference to the cams, it is pointed out that the cam surfaces of the cams 53 and 58 are so relatively timed and configured that when the bars H are moving to the right in their outermost positions or to the left in their innermost positions, the hub members 33 and the collars 44 are moved axially of the shaft 4! at the same speed, so that there is no relative movement therebetween, and that when the ars are moving inwardly or outwardly there is relative axial movement between the hub members and collars toward or away from each other to cause the links 43 to 'tnove the bar carrying arcuate members in or out as the case may be. This is also true with respect to the cams 54 and Ill, which actuate the bars 32.

In order to collect liquids which would otherwise drip over certain of the parts of the actuating mechanism above described, I have provided inner shields or troughs 33a and 31a of V- shaped form which are carried by the arcuate supports 33 and 31 respectively and which extend lionggzudinally of the cage C as shown in Figures It is pointed out that the driving mechanism for the cage and the cam actuating mechanism D for the bars, with the exception of the bar supports and reciprocating actuating rods, are 10- cated beyond the end of the cage itself out'of employing acage of' large diameter rotating at slow speed, these drive shafts may be driven at such relative speeds that the case will make one revolution for each forwardstroke 6f the bars. When employing a cage of smaller diameter and higher rotative speed, these shafts may be driven at such relative speeds that the cage 4 will make several revolutions for each forward stroke of the bars as is the case in the machine illustrated in the drawings. Thus high speed spinning may be accomplished without rapid shuttling action of' the bars. 'Thus wear of the parts is minimized.

It is to be observed that a cage mechanism Q constructed in accordance with my invention employs considerably fewer ports than previous mechanisms and that because of its construction very strong and rigid cages of very large size may ment to the right in the outer positions of both sets of bars just referred to avoids ahy possibilityof there being a time, in the cycle at which no bars are moving to the right in outer position as would he the case if the bars of one set should start to move in and to the left before the bars of the other set had reached their outermost posibe provided.

Referring now to the cage B which is diagrammatically illustrated in Figure 1 and in detail in Figures 21 to 24 inclusive, it will be seen from inspection of Figure 1 that the bundle of filaments or thread is laid up on this cage in the form ofa continuously advancing helix Just as it is laid up on the cage C, the construction of the bars and the actuating mechanism therefor however being of different construction, as will now appear.

The cage in this instance is comprised of two sets of bars arranged in cylindrical formation with the bars 13 of one set in circumferentially evenly spaced interspersed relation with the bars I! of the other set. The bars of each set are atto rock, This oscillates the disc I02 and operranged in concentric groups. In this instance I have shown each set cf-bars arranged into three groups with each group including eight bars.

The bars 18 are in the form of outstanding longitudinally extending ribs provided on the arcuate members 80 which are secured to arcuate supports BI. Each arcuate support has an in wardly extending radialarm 82 provided at its inner or free end with a forked-portion 83 which straddles a central longitudinally extending drive shaft 84. Each of theradial arms 82 carries a longitudinally extending rod 85 at a point adjacent its arcuate support 8|. These rods 85 fit the bifurcated ends 88 of the spokes 81 of a spoked driving member 88 which is secured to the drive shaft 84 to rotate therewith, and it will be seen, therefore, that when the spoked driving member 88 is rotated the arcuate members 80 are also rotated.

The bars 19 of'the other set are secured to arcuate supports 89 each having an inwardly extending radial arm 90 provided at its inner or free end with a forked portion 9 I which straddles the drive shaft 84.- Each arm 90 carries a longitudinally extending rod 92 at a point adjacent its arcuate support 89. These rods 92 fit the bifurcated ends 93 of the spokes 94 of the spoked driving member 88 above referred to. Thus the rods 92 rotate with the driving member 88 and since these rods are carried by the arms of the arcuate supports 89 it will be seen that the bars 19 rotate with the driving member 88.

Longitudinal back and forth and radial in and out movements are imparted to the bars 18 and 19 by means of a pair of stationary cams 95 and 95a and. associated actuating mechanism now to be-described. The earns 95 and 95a are fixedly secured to a suitable fixed support such as the frame member shown at 95f'in Fig. 22.

The actuating mechanism for actuating the bars 18 comprises a rocker arm 96 carrying grooved cam rollers 91 and 98, and secured on a rock shaft 99. The rock shaft 99 is mounted in one of the spokes 81 of the spoked driving member 88 with freedom for turning movement and also for back and forth longitudinaLmovement and extends through a slot I in the arm 82 of one of the arcuate supports 8| for the bars 19, said arm 82 being aligned with the spoke 81 whichcarries the rock shaft 99, as shown in Figure 2 1. The rock shaft 99 is provided with fixed collars IOI, IOI abutting against the sides of said arm '82 so that when the rock shaft is shifted" in an axial direction the bars will move therewith in a longitudinal direction. The rock shaft 99 has a disc I02 secured thereon which is provided with three circumferentially spaced pins for receiving one end of the links I 03. The other ends of these links are connected to the rods 85 above referred to. It will thus be seen that when the rock shaft 99 is rocked the disc moves therewith and causes radial in' and out movement of the bars 18 through the medium of the links I03.

Rocking movement is imparted to the rock shaft 99 by means of the rollers 91 and 98 and the the surface 95b of the cam 95a, and as rotationcontinues the roller rides onto the surface I of the cam 95a, thus causing the rock shaft 99 point where the roller 98 rides off the surface I05" the roller 91 engages the surface 950 of the cam 95 and as rotation'continues the roller 91 rides onto the surface I04 of the cam 95 thus rocking the rock shaft back to the position shown in Figure 21 and moving the bars 19 outwardly again.

It is pointed out that the cams 95 and 95a are disposed at an angle as viewed in Figure 22 and therefore as the grooved rollers travel around the cams they are also moved longitudinally back and forth because of the inclined disposition of the cams. Thus the rock shaft 99, the disc I02, the links I03, the arcuate supports 8I and the bars 18 are accordingly moved longitudinally back and forth, the movement in one direction being imparted by the cam 95 and in the opposite direction by'the cam 95a. The cam surfaces are so calculated and related that the movement imparted to the bars is similar to the movement above described in connection with the bars of the cage C. v

The actuating mechanism for the bars 19 is similar to the actuating mechanism for the bars 18 just described, and comprises a rocker arm I06 carrying grooved cam rollers I01 and I08, a rock shaft I09 carried by one of the spokes 94 of the member 88 and extending through a slot H0 in the arm of one of the arcuate supports 89- for the bars 19, the collars -III on the rock shaft abutting against the sides of the arm 90, a disc II2 secured on the rock shaft, and links II3 connecting the disc II2 to the rods 92 above described. Since the actuating mechanism operates the same as the actuating mechanism for the bars 18 its operation will be understood from the above.

It is pointed out that in Figures 21 to 24 Lhave only shown the supports and actuating connection which are located at one end portion of the cage, but it is to be understood that similar parts are employedat 'the other end portion of the cage and at intermediate points along the cage.

The bars 18 and 19 are provided with facings II4 of material such as sponge rubber for the purpose of preventing copper hydroxide from caking on the faces of. the bars as would be the case if metal facings were employed. Preferably the supporting faces ,of the sponge rubber are made substantially impervious.

experienced in attempting to remove the caked copper hydroxide by mechanical means. The

' sponge rubber facings prevent the above because .65 surfaces I04 and'I05 of the cams and 95a, it."

of the yieldable character thereof which causes the surface on which the thread is laid to be continuously flexed by the thread due to its tension. With the surface flexing in this manner the precipitated copper is kept in motion and therefore will not form into a cake because the growth of the crystals is prevented as well'as their adhesion, one to another, so that they may be compared with very loose snow flakes which.

either fall off by their own weight or are removed by the washing liquids. a plain metallic surface the crystals tend to pack In this connec-, tion it is pointed out that with metal facings the 0n the other hand, on

of different'form from the bar actuating mechanism for the cage C, I contemplate employing actuating mechanism of either of these forms for both cases.

I claim:

1. Apparatus for laying up thread in the form of a continuously advancing helix, comprising a rotating cage-like thread carrying cylinder; said cylinder comprising two concentric sets of circumferentially spaced longitudinally extending bars, the bars of one set being in interspersed relation to the bars of the other set; means connecting the bars of each set into a plurality of units each comprising a plurality of bars, radially disposed members carried by said connecting means; actuating mechanism for imparting back and forth, longitudinal movement and in and out radial movement to the bar units of each set independently; and means connecting said actuating mechanism to said radially disposed members.

2. Apparatus for layingup thread in the form of a continuously advancing helix, comprising a rotating cage-like thread carrying cylinder; means for guiding thread onto said cylinder ad Jacent one end thereof; said cylinder comprising two. sets of circumferentially spaced longitudishaft extending longitudinally of said cylinder;

a. plurality of spoked supporting members splined on said shaft, the spokes of which receive said radial arms with capacity for radial in andout movement; a plurality of collars splined on said drive means for rotating said cams, said drive shaft in association with said spoked members;

, links connecting said collars to said radial arms,

means for moving said spoked members back and forth on said shaft; and means for moving said collars back and forth on said shaft; said spoked members when so moved transmitting longitudinal back and forth movement to the bars and said collars when so moved transmitting radial in and out movement to the bars.

3. Apparatus for laying up thread in the form of a continuously advancing helix, comprising a rotating cage-like thread carrying cylinder; means for guiding thread onto said cylinder adjacent one end thereof; said-cylinder comprising two sets of circumferentially spaced longitudinallyextending bars, with the bars of one set interspersed with those of the other set; a pluralityof arcuate supports for the bars of each set dividing the sets into a plurality of groups of bars; radially inwardly extending arms carried by said arcuate supports; a central drive shaft extending longitudinally of said cylinder; a plurality of spoked supporting members splined on said shaft, the spokes of which receive said radial arms with capacity for radial in and out movement; a plurality of collars splined on said shaft in association with said spoked members; links connecting said collars to said radial arms; drive means for rotating said drive shaft; rotatable cams for moving said spoked members back and forth on said shaft; rotatable cams-for moving s id collars back and forth on said shaft;

means-being independent of the drive means for means for guiding thread onto said cylinder adiacent one end thereof; said cylinder comprising two sets ofcircumferentially spaced longitudinally extending bars, with the .bars of one set interspersed with those of the other set; a plurality of arcuate supports for the bars of each set dividing the sets into a plurality of roups oi bars; radially inwardly extending arms carried by said arcuate supports; a central drive shaft extending longitudinally of said cylinder; a plurality of spoked supporting members splined on said shaft, the spokes of which receive said radial arms with capacity for radial in and out movement; a plurality of collars splined on said shaft in association with said spoked members; links connecting said collars to said radial arms; drive means for rotating said drive shaft including a worm wheel secured on the drive shaft and a driving worm for said worm wheel; a supporting member mounted coaxially with said drive shaft for rotation therewith; rotatable cams and associated actuating means for imparting back and forth movement to said spoked members; rotatable cams and associated actuating means for imparting back and fortlrmovement to said collars; worm wheels rotatable with said cams; transverse bearings carried by said supporting member for said cams and worm wheels; and a driving worm for said cam worm wheels mounted coaxially with said drive shaft for rotation independently thereof.

5. Apparatus for laying up thread in the form of a continuously advancing helix, comprising a rotating cage-like thread carrying cylinder; iixed means for guiding thread onto said cylinder adjacent one end thereof; said cylinder comprising two sets of circumferentially spaced longitudi-- for connecting said member and the set of barsfor reciprocation together; other means associ- 'ated with each set for imparting movement thereto in directions inwardly and outwardly ofmeans for guiding thread on said cylinder ad- Jacent one end thereof; a pair of independently movable sets of longitudinally extending bars, the bars of said sets being arranged in interspersed and spaced relation to constitute said thread carrying cylinder; cam mechanism for 'each set adapted to impart in and out and back and forth longitudinal movement thereto, the cam mecha- 1 nism of each set comprising a rotatable cam adapted to impart said in and out movement, a

- rotatable cam adapted to impart said back and being connected to said first mentioned reciprocating member for reciprocation thereby, linkage means connecting said collar to said set of bars to impart in and out movement thereto when the collar is reciprocated back and forth, and means for effecting rotation of said cams; the cam mechanism of said two sets of bars being so relatively set that duringone revolution of the cams one of the sets moves out and then starts forwardly in the direction of advance of the helix just prior to the time that the other set reaches the end of its forward stroke, that said first mentioned set then continues in forward stroke while the second mentioned set moves in, on its backward stroke, and then out again, and that said second mentioned set then starts forwardly just prior to the time that'said first mentioned set reaches the end of its forward stroke, and so on whereby an uninterrupted continuously advancing helix is laid on the cylinder.

7. Apparatus for laying up thread in the form of a continuously advancing helix, comprising a rotating cage-like thread carrying cylinder; fixed means for guiding thread onto said cylinde'r adjacent one end thereof; said cylinder comprising two sets of circumferentially spaced'longitudinally extending bars, with the bars of one set interspersed with those of the other set: means associated with each set for imparting movement thereto indirections back and forth longitudinally of the. cylinder comprising cam means, a member reciprocated by said cam, and means connecting said member and the set of bars for reciprocation together; and means associated with each set for imparting movement thereto in directions inwardly and outwardly of said cylinder, comprising the aforesaid cam means, a rock shaft having a member engaging said cam means to effect rocking movement of the rock shaft, and means connecting said rock shaft to the set of bars'to move it inwardly and outwardly. Y

8. Apparatus for laying up thread in the form of a continuously advancing helix, comprising a rotating cage-like thread carrying cylinder;- flxed means for guiding thread onto said cylinder adjacent one end thereof; said cylinder comprising two sets of circiunferentially spaced longitudinally extending bars, with the bars of one I set interspersed with those of the other set;

means associated with each set for imparting movement thereto in directions back and forth longitudinally of the cylinder comprising stationary cam means, a member reciprocated by said cam means when the cylinder is rotating, andmeans for connecting said member and the set of bars for reciprocation together; means associated with each setfor imparting movement thereto in directions inwardly and outwardlyof said cylinder, comprising said cam means and linkage operable thereby when the cylinder is rotating and connected to the set of bars; a fixed support for said cam means; and means for rotating said cylinder.

WILLIAM H. FURNESS. 

